Zeólitas hierarquicamente estruturadas

Grecco, Saulo de Tarso Figueiredo; Rangel, María do Carmo; Urquieta‐González, Ernesto A.

doi:10.1590/s0100-40422013000100023

Cited by 17 publications

(9 citation statements)

References 57 publications

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“…Synthetic zeolites are formed at a temperature ranging from 80 ºC to 200 ºC (Cundy and Cox 2003;Viera et al, 2014). Due to their structural characteristics, zeolites have some unique properties that make them useful in many industrial applications, such as high specific surface area; pores, channels and cavities of molecular dimensions that impart different types of selectivity; high adsorption capacity, ease of separation of reactants and products; high thermal stability associated with higher Si/Al ratio and internal acidity, responsible for zeolite action as catalysts (Corma, 2003;Grecco and Rangel, 2013). A wide variety of applications for zeolites includes: agriculture, processing of radioactive materials and contaminated soils, removal of toxic metals, softener of industrial and domestic water, purification and separation of industrial gases, animal nutrition, catalysis and oil refining, as well as other applications (Luna and Schuchardt, 2001;Silaghi et al, 2014;Jamieson et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Synthesis of Zeolite 4a for Obtaining Zeolite 5a by Ionic Exchange for Full Utilization of Waste From Paper Industry

Moreira

Santa

Nones

et al. 2018

Braz. J. Chem. Eng.

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In order to minimize environmental impact zeolite A was synthesized using waste from the paper industry. This waste is composed of cellulose, kaolin and calcium carbonate. Waste purification was carried through thermal and chemical treatment, which consisted of initial calcination, acid washing with HCl, then calcination of the solid fraction to obtain metakaolin and evaporation of the liquid fraction to obtain CaCl2. Zeolite 4A was produced by static autoclaving under hydrothermal synthesis at different temperatures, crystallization times and NaOH concentrations. As a source of aluminum and silicon metakaolin was used. The synthesis of zeolite 5A was performed by ion exchange with CaCl2. After that, the waste paper (in natura and HCl treatment) and the zeolites 4A and 5A were characterized by XDR, SEM, FTIR, AAS and thermal analysis. The temperature is a key factor in zeolite synthesis at lower concentrations allowing one to obtain zeolite 5A by ion exchange with zeolite 4A.

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Section: Introductionmentioning

confidence: 99%

Synthesis of Zeolite 4a for Obtaining Zeolite 5a by Ionic Exchange for Full Utilization of Waste From Paper Industry

Moreira

Santa

Nones

et al. 2018

Braz. J. Chem. Eng.

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“…The size and shape of porous channels provide selectivity to zeolites, enabling changes in morphology, composition and porosity, as well the combination of active species with material structure. [1][2][3] In addition to their properties as molecular sieves, zeolites also chemically interact with some molecules due to their surface acidity provided by structural aluminum atoms or by charge imbalance from broken bonds at the structural extremities. [4][5][6] Zeolites are generally synthesized under hydrothermal conditions using hydrogels prepared from aluminate, silicate and hydroxide solution.…”

Section: Introductionmentioning

confidence: 99%

Synthesis, Optimization and Characterization of Zeolite Beta (BEA): Production of ZSM-5 and NaAlSiO4 as Secondary Phases

Nascimento¹,

Figueredo²,

Silva³

et al. 2017

Rev. Virtual Quim.

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. Em outros ensaios, foram obtidas fases secundárias de NaAlSiO 4 e SiO 2 , bem como zeólita ZSM-5, analcima, omega e Linde B2.Palavras-chave: BEA; razão Si/Al; Tempo; Temperatura. AbstractThe choice of synthesis parameters influences obtainment of a suitable material for use in several applications. In this paper, zeolite beta (BEA) was successfully obtained by hydrothermal synthesis, assessing the following parameters: Si/Al ratio, time and crystallization temperature. The synthesized materials were characterized by X-ray diffraction (XRD), Fourier-Transfer Infrared (FTIR) spectroscopy, thermogravimetry (TG and DTG) and N 2 adsorption-desorption isotherm analyses. Xray diffraction showed that the change of only one of these parameters acts on the formation of the desired microporous structure. BEA was obtained in the Si/Al ratio equal 8, with a crystallization time of 4 days at 170 °C, presenting a specific area of 437 m . In other assays, secondary phases of NaAlSiO 4 and SiO 2 were obtained, as well as ZSM-5 zeolite, analcime, omega and linde B2.

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“…At low angles (Figure 1), the XRD pattern of pure MCM‐41 (SiO 2 /Fe 2 O 3 = ∞) exposes a typical mesoporous structure whose peak is 2 θ = 2.8°, which indicates that it is a highly ordered hexagonal structure 29,36,37 . Diffraction peaks in the region of low angles originated from the mesopore results in a long‐range organization of amorphous materials 25,34,45 . It should be emphasized that peak intensities of modified samples gradually decreased with metal incorporation, which indicates the formation of a less ordered structure 28,29,34,42 .…”

Section: Resultsmentioning

confidence: 99%

Fe₂O₃/MCM‐41 as catalysts for methyl orange degradation by Fenton‐like reactions

Santana

Bonfim

Cruz

et al. 2020

Env Prog and Sustain Energy

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A large amount of contaminated industrial wastewater has aroused mounting concern by researchers and environmentalists. Dyes contained in industrial effluents are often quite persistent to biodegradation, which must be treated before being disposed of. In this context, the use of Fenton processes is a potential alternative to treat a wide range of dyes and other organic pollutants found in wastewater. Thus, several Fe2O3/MCM‐41 catalysts have been synthesized in the following molar ratio of SiO2/Fe2O3: 10, 20, 40, 100, and 200. They were characterized by N2 adsorption–desorption isotherm, X‐ray fluorescence (XRF), X‐ray diffraction (XRD), UV–vis spectroscopy and H2 temperature‐programmed reduction (H2‐TPR), and applied to degrade methyl orange dye (MO) via a heterogeneous Fenton reaction. Catalytic tests revealed that SiO2/Fe2O3 = 10 reached the highest activity due to greater availability of active sites which generated a larger quantity of hydroxyl (•OH) and perhydroxyl (•OOH) radicals. Furthermore, 70% of color removal has been achieved after 120 min at room temperature. Moreover, the systems moderately enhanced organic matter mineralization according to chemical oxygen demand (COD) testing. There was also catalytic activity loss in consecutive reaction cycles, which is probably due to dye molecules adsorption on active sites.

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Zeólitas hierarquicamente estruturadas

Cited by 17 publications

References 57 publications

Synthesis of Zeolite 4a for Obtaining Zeolite 5a by Ionic Exchange for Full Utilization of Waste From Paper Industry

Synthesis of Zeolite 4a for Obtaining Zeolite 5a by Ionic Exchange for Full Utilization of Waste From Paper Industry

Synthesis, Optimization and Characterization of Zeolite Beta (BEA): Production of ZSM-5 and NaAlSiO4 as Secondary Phases

Fe₂O₃/MCM‐41 as catalysts for methyl orange degradation by Fenton‐like reactions

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Zeólitas hierarquicamente estruturadas

Cited by 17 publications

References 57 publications

Synthesis of Zeolite 4a for Obtaining Zeolite 5a by Ionic Exchange for Full Utilization of Waste From Paper Industry

Synthesis of Zeolite 4a for Obtaining Zeolite 5a by Ionic Exchange for Full Utilization of Waste From Paper Industry

Synthesis, Optimization and Characterization of Zeolite Beta (BEA): Production of ZSM-5 and NaAlSiO4 as Secondary Phases

Fe2O3/MCM‐41 as catalysts for methyl orange degradation by Fenton‐like reactions

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Fe₂O₃/MCM‐41 as catalysts for methyl orange degradation by Fenton‐like reactions